Diagnosing Nutrient Deficiencies in Soybean, Using M‐DRIS and Critical Nutrient Level Procedures

Bell, Paul F.; Hallmark, W. B.; Sabbe, W. E.; Dombeck, D. G.

doi:10.2134/agronj1995.00021962008700050013x

Cited by 19 publications

(14 citation statements)

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“…The range for P in that same study is 0.31 to 0.50% for sufficiency, and less than 0.31% to be deficient in P. In Arkansas, soil and plant diagnostic tests are done in a site-specific manner, where plants from a good area of the field are compared to plants from a poor area in that same field. We find tissue levels of P and K in soybean are often at the lower ends of the ranges listed in Bell et al (1995). Frequently plants that have deficient levels of P and K do not result in yield reduction.…”

Section: Leaf Starch and Nitrogen Relationship With Leaf Phosphorus Amentioning

confidence: 75%

“…A recent survey of the combined data banks for nutrient levels of soybean grown in Alabama, Arkansas, Iowa, Georgia, and Louisiana report the recommended critical nutrient concentrations of K to be between 1.25 and 2.5% for sufficiency, and below 1.51% for deficiency (Bell et al, 1995). The range for P in that same study is 0.31 to 0.50% for sufficiency, and less than 0.31% to be deficient in P. In Arkansas, soil and plant diagnostic tests are done in a site-specific manner, where plants from a good area of the field are compared to plants from a poor area in that same field.…”

Section: Leaf Starch and Nitrogen Relationship With Leaf Phosphorus Amentioning

confidence: 99%

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Starch and nitrogen status in soybean during shading and nutrient deficiency

Ball

Sabbe

DeLong

1998

Journal of Plant Nutrition

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Plant mineral requirements are based on nutrient prediction models, but plant energy is seldom taken into consideration. Starch, a potential indicator of plant energy reserve, was assessed by first investigating the association between leaf starch and nitrogen (N) during and after shading, and secondly by quantifying leaf phosphorus (P) and potassium (K) content to the starch-N relationship. Soybeans [Glycine max (L.) Merr] were field-grown in 1992, 1993 and 1994 at Fayetteville, Arkansas, and shaded during vegetative and reproductive growth (V7 to R4). The 1994 shading study also incorporated a treatment of K and P fertilizer. Starch and N levels (% leaf DW) were predicted from calibration models based on spectra produced by near infra-red spectroscopy. Starch measured at 1,800 h was reduced by shading, declined after flowering, and was more strongly associated with radiation and leaf N as growth stage R4 was reached. The range of starch concentration in leaf tissue was from zero to 18% leaf DW, and nitrogen varied from 3.5 to 5.5% leaf DW. Starch and N levels were inversely related for leaves located at or near the top of the plant canopy. From covariant analysis, we did not find the starch-N relationship to change with differing K content of leaves from the 1994 study. Leaf samples with low and high P content showed differences in the slopes of the starch-N curves due to the mild nutrient stress. The starch-N relationship may be useful in identifying plants affected by P deficiency. 665

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Section: Leaf Starch and Nitrogen Relationship With Leaf Phosphorus Amentioning

confidence: 75%

Section: Leaf Starch and Nitrogen Relationship With Leaf Phosphorus Amentioning

confidence: 99%

Starch and nitrogen status in soybean during shading and nutrient deficiency

Ball

Sabbe

DeLong

1998

Journal of Plant Nutrition

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“…Although these effects of Mn treatment were significant, the concentrations were three to four times greater than those seen in the greenhouse experiment. These concentrations are relatively high but are considered nontoxic for soybean growth (Bell et al, 1995)…”

Section: Resultsmentioning

confidence: 99%

Soybean Cultivar Differences in Ureides and the Relationship to Drought Tolerant Nitrogen Fixation and Manganese Nutrition

Purcell¹,

King²,

Ball³

2000

Crop Science

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Water deficit in soybean [Glycine max (L.) Merr.] results in the accumulation of the products of N2 fixation (ureides) in shoots, and this may lead to feedback inhibition of N2 fixation. Manganese is required for ureide degradation in leaves, and it was hypothesized that increased leaf Mn+2 would alleviate ureide accumulation during drought, lessen feedback inhibition, and prolong N2 fixation. In a growth chamber experiment, ureides supplied through roots decreased N2 fixation in well‐watered plants, and a soybean cultivar with demonstrated tolerance of N2 fixation to water deficit (Jackson) had a lesser concentration of shoot ureides following exogenous ureide application than a cultivar sensitive to water deficit (KS4895). In a greenhouse experiment, N2 fixation in Jackson under moderate water deficit was not different from the control in the absence or presence of soil‐applied Mn+2, whereas N2 fixation in KS4895 was 30% of the control in the absence of soil‐applied Mn+2 and 111% of the control in the presence of soil‐applied Mn+2 Increased N2 fixation in KS4895 with soil‐applied Mn+2 under water deficit was associated with decreased shoot ureide concentration. In field experiments, Jackson consistently had lesser shoot ureide concentrations than did KS4895, and enzymatic degradation of ureides was greater for Jackson on one date than for KS4895. We concluded that ureides inhibit N2 fixation, that genetic variation in the ability to degrade ureides may be important in drought tolerance, and that increased leaf Mn+2 concentration promotes ureide breakdown and prolongs N2 fixation under water deficit.

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“…The selection of the right P c will undoubtedly be some function of the rate of acceptable failure to several different groups, including farmers, environmental groups and organizations, and private entities such as the insurance industry. Beverly's ER (Table 5) is one example of a weighting scheme that has been used in the tissue‐diagnostics literature (Bell et al, 1995; Beverly, 1993). His approach strongly favors the farmer's yield‐loss concerns (Beverly and Hallmark, 1992, Beverly 1993).…”

Section: Resultsmentioning

confidence: 99%

Diagnostic Efficiency of the Blacklayer Stalk Nitrate and Grain Nitrogen Tests for Corn

2000

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Protecting water quality and maintaining profitable corn (Zea mays L.) production requires diagnostics that can distinguish between N deficiency, sufficiency, and excess. This study evaluates initial recommendations on blacklayer basal‐stalk NO3–N ranges and critical concentrations for diagnosing N status, and it compares the performance of this test with grain analysis. Observations (428) were collected from 13 N‐response experiments. Linear response and plateau (LRP) and binary logistic regression (BLR) were used to characterize the relationships between yield and tissue‐test values. With the LRP, stalk NO3–N and grain N concentrations separating deficient from sufficient observations were 0.42 and 13.1 g kg−1, respectively, and the success rates of the two tests were comparable (77 and 75%, respectfully). The BLR also identified critical concentrations, but the values increased with decreasing yields, a desirable decision‐rule attribute given that extreme deficiency can result in higher‐than‐expected tissue concentrations. The success rates of multiple BLR functions using yield and stalk or grain analysis as factors were again comparable (88 and 87%, respectively), but they were significantly greater than with the LRP analysis. Stalk analysis was superior to grain analysis for distinguishing sufficiency from excess. A constant stalk NO3–N concentration (1.67 g kg−1) separated sufficient from excessive cases, and fertilizer efficiency approached zero at 2.9 g kg−1. Premature sampling resulted in stalk NO3–N levels that were 40 to 600% greater than levels observed after blacklayer formation, with the greatest error occurring when N fertility was low. When not testing for N excess, the advantages of grain analysis are the ease of sampling during harvest and the reduced risk of error associated with premature sampling.

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Diagnosing Nutrient Deficiencies in Soybean, Using M‐DRIS and Critical Nutrient Level Procedures

Cited by 19 publications

References 0 publications

Starch and nitrogen status in soybean during shading and nutrient deficiency

Starch and nitrogen status in soybean during shading and nutrient deficiency

Soybean Cultivar Differences in Ureides and the Relationship to Drought Tolerant Nitrogen Fixation and Manganese Nutrition

Diagnostic Efficiency of the Blacklayer Stalk Nitrate and Grain Nitrogen Tests for Corn

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